A communication network encrypts a first portion of a transaction associated with point-to-point communications using a point-to-point encryption key. A second portion of the transaction associated with end-to-end communications is encrypted using an end-to-end encryption key.
|
11. A first computer having a processor configured for:
establishing a first security association with a second computer;
encrypting first data of a first data path in a transaction using the first security association, wherein:
the first data path is through an intermediary server that provides connectivity between the first computer and the second computer;
the first security association is not known to the intermediary server; and
the transaction comprises a transaction message that includes control data and payload data;
transmitting the control data to the intermediary server, wherein:
the control data includes a token associated with the intermediary server;
the token provides transaction routing information;
the second computer receives the first data from the intermediary server; and
the second computer decrypts the first data;
encrypting second data of a second data path using a second security association, wherein the second data path is distinct from the intermediary server; and
transmitting the payload data through the second data path.
1. A method implemented on a first computer, the method comprising:
establishing a first security association with a second computer;
encrypting first data of a first data path in a transaction using the first security association, wherein:
the first data path is through an intermediary server that provides connectivity between the first computer and the second computer;
the first security association is not known to the intermediary server; and
the transaction comprises a transaction message that includes control data and payload data;
transmitting the control data to the intermediary server, wherein:
the control data includes a token associated with the intermediary server;
the token provides transaction routing information;
the second computer receives the first data from the intermediary server; and
the second computer decrypts the first data;
encrypting second data of a second data path using a second security association, wherein the second data path is distinct from the intermediary server; and
transmitting the payload data through the second data path.
21. A non-transitory computer-readable storage medium, the non-transitory computer-readable storage medium storing instructions to be implemented on a first computer including at least one processor, the instructions when executed by the at least one processor cause the first computer to perform a method, the method comprising:
establishing a first security association with a second computer;
encrypting first data of a first data path in a transaction using the first security association, wherein:
the first data path is through an intermediary server that provides connectivity between the first computer and the second computer;
the first security association is not known to the intermediary server; and
the transaction comprises a transaction message that includes control data and payload data;
transmitting the control data to the intermediary server, wherein:
the control data includes a token associated with the intermediary server;
the token provides transaction routing information;
the second computer receives the first data from the intermediary server; and
the second computer decrypts the first data;
encrypting second data of a second data path using a second security association, wherein the second data path is distinct from the intermediary server; and
transmitting the payload data through the second data path.
4. The method of
5. The method of
6. The method of
7. The method of
8. The method of
9. The method of
14. The first computer of
15. The first computer of
16. The first computer of
17. The first computer of
18. The first computer of
19. The first computer of
24. The method of
25. The method of
26. The method of
27. The method of
28. The method of
29. The method of
|
This application is a continuation of U.S. patent application Ser. No. 16/176,946 filed Oct. 31, 2018, entitled “SECURE END-TO-END TRANSPORT THROUGH INTERMEDIARY NODES”, which is a continuation of U.S. patent application Ser. No. 15/639,014 filed Jun. 30, 2017, entitled “SECURE END-TO-END TRANSPORT THROUGH INTERMEDIARY NODES”, now U.S. Pat. No. 10,135,771 which issued Nov. 20, 2018, which is a continuation of U.S. patent application Ser. No. 15/140,284 filed Apr. 27, 2016, entitled “SECURE END-TO-END TRANSPORT THROUGH INTERMEDIARY NODES”, now U.S. Pat. No. 9,712,476 which issued Jul. 18, 2017, which is a continuation of U.S. patent application Ser. No. 14/043,772 filed Oct. 1, 2013, entitled “SECURE END-TO-END TRANSPORT THROUGH INTERMEDIARY NODES”, now U.S. Pat. No. 9,344,393 which issued May 17, 2016, which is a continuation of U.S. patent application Ser. No. 13/396,464 filed Feb. 14, 2012, entitled “SECURE END-TO-END TRANSPORT THROUGH INTERMEDIARY NODES”, now U.S. Pat. No. 8,549,587 which issued Oct. 1, 2013, which is a continuation of U.S. patent application Ser. No. 12/889,252, filed Sep. 23, 2010, entitled “SECURE END-TO-END TRANSPORT THROUGH INTERMEDIARY NODES”, now U.S. Pat. No. 8,127,342 which issued Feb. 28, 2012, which is a continuation of U.S. patent application Ser. No. 11/875,785 filed Oct. 19, 2007, titled “SECURE TRANSPORT FOR MOBILE COMMUNICATION NETWORK”, now U.S. Pat. No. 7,827,597 which issued Nov. 2, 2010, which is a continuation of U.S. patent application Ser. No. 10/339,369 filed Jan. 8, 2003, titled “SECURE TRANSPORT FOR MOBILE COMMUNICATION NETWORK”, now U.S. Pat. No. 7,305,700 which issued Dec. 4, 2007, which claims benefit of U.S. Provisional Application No. 60/346,881 filed Jan. 8, 2002, titled “MOBILE DATA SERVICES” and claims benefit of U.S. Provisional Application No. 60/403,249 filed Aug. 12, 2002, titled “MOBILE DATA SERVICES”. The disclosure of each of the aforementioned applications is incorporated herein by reference in their entireties.
Security is a concern when information is transferred over the Internet. Encryption technology may be used to protect data transferred between two nodes communicating across a network such as the Internet. The Internet infrastructure involved in transferring a particular set of data may include one or more intermediary network processing nodes that need to process different portions of the data in order to correctly route the packets between the two endpoints.
The intermediary network processing nodes may be given access to the encryption key used to encrypt the data. However, decrypting the packets at the intermediary points presents a security risk. For example, an eavesdropper may be able to access the data after being decrypted at the intermediary network processing nodes.
The present invention addresses this and other problems associated with the prior art.
A communication node encrypts a first portion of a transaction associated with point-to-point communications using a point-to-point encryption key corresponding to a first security association. A second portion of the transaction associated with end-to-end communications is encrypted using an end-to-end encryption key corresponding to a second security association.
The foregoing and other objects, features and advantages of the invention will become more readily apparent from the following detailed description of a preferred embodiment of the invention which proceeds with reference to the accompanying drawings.
The transfer of different types of data may be referred to below generally as a transaction. These transactions can be used for transferring email data, calendars, contacts, tasks, notes, electronic documents, files or any other type of control or content data.
The enterprise network 18 can be any business network, individual user network, or local computer system that maintains local email or other data for one or more users. In the embodiment shown in
The PC 38 is connected to the email server 34 over a Local Area Network (LAN) 35. The PC 38 includes memory 39 for storing local files that may include personal email data as well as any other types of electronic documents. Personal client software 40 is executed by a processor 37 in the PC 38. The personal client 40 enables access to email, calendars, and contact information as well as local files for mobile device 21.
The communication management system 16 includes at least one management server 28 that includes a processor 33. The processor operates a transfer agent 31 that manages the transactions between the mobile device 21 and the enterprise network 18. A user database 42 includes configuration information for different users of a mobile communication server. For example, the user database 42 may include login data for user of the mobile communication server. While referred to as a management system 16 and management server 28, this can be any intermediary system that includes one or more intermediary servers that operate between the mobile network 14 and the enterprise or private network 18.
The personal client 40 makes an outbound connection 25 to the management server 28. The personal client 40 registers the presence of a particular user to the management server 28 and negotiates a security association specifying a cryptographic ciphersuite (including encryption cipher, key length, and digital signature algorithm) and a unique, secret point-to-point encryption key 29 over connection 25. In one example, the key 29 is an Advanced Encryption Standard (AES) key, which is negotiated using the Diffie-Hellman cryptographic algorithm. Of course, encryption ciphers other than AES can also be used. The encryption key 29 enables secure communication between management server 28 and PC 38 over connection 25.
The mobile device 21 negotiates a point-to-point security association, specifying a cryptographic ciphersuite and a unique encryption key 27, with the management server 28. In one example, the point-to-point encryption key 27 is an AES encryption key. The negotiated security association that includes encryption key 27 enables secure point-to-point communication between the mobile device 21 and the management server 28 over connection 23. Each different mobile device 21 must negotiate a different security association that includes a unique encryption key 27 with the management server 28.
The point-to-point encryption key 27 may be used for encrypting control data that needs to be transferred between the mobile device 21 and management server 28. The point-to-point encryption key 29 may be used for encrypting control data that needs to be transferred between the management server 28 and personal client 40. For example, the control data may include login information and transaction routing information.
An end-to-end security association, specifying a cryptographic ciphersuite and a unique encryption key 46, is negotiated between the mobile device 21 and the personal client 40. In one example, the end-to-end encryption key 46 is an AES encryption key. The end-to-end encryption key 46 is used for encrypting transaction payloads transferred between personal client 40 and mobile device 21. For example, the end-to-end encryption key 46 may be used for encrypting the content of emails, files, file path names, contacts, notes, calendars, electronic documents and any other type of data that needs to be securely transferred between mobile device and the PC. The end-to-end encryption key 46 is only known by the mobile device 21 and the personal client 40. Data encrypted using the end-to-end key 46 cannot be decrypted by the management server 28.
The management server 28 decrypts the portion 63A of the transaction 60 encrypted using the point-to-point encryption key 27. Since server 28 does not have encryption key 46, portion 65 is not decrypted. The management server 28 decodes any unencrypted data 61A and the decrypted point-to-point data 63A to determine how to process the synchronization transaction 60A. Part of the processing may include re-encrypting some or all of the decrypted data 63A back into point-to-point encrypted data 63B using encryption key 29. The management server 28 may also modify or add to the unencrypted data 61A to generate new unencrypted data 61B. The unencrypted data 61B and the re-encrypted point-to-point data 63B are combined with the end-to-end encrypted data 65 to generate new synchronization transaction 60B. The transaction 60B is transported to personal client 40 over the connection 25.
The personal client 40 decrypts the point-to-point encrypted data 63B using the encryption key 29 and decrypts the end-to-end encrypted data 65 using the encryption key 46. The personal client 40 obtains email messages 62 from the mailbox 44 pursuant to the decrypted instructions in synchronization transaction 60B. The personal client 40 encrypts the content of the email messages 62 using the end-to-end encryption key 46.
The personal client 40 generates a response transaction 66A that may attach an envelope 64A to the end-to-end encrypted email messages 62. The envelope 64A may contain communication parameters identifying transaction 66A as a response to the synchronization transaction 60B and may contain other message parameters such as the size of the email messages 62.
Some or all of the envelope 64A may be encrypted using the point-to-point encryption key 29. The personal client 40 then sends message 66A to the management server 28. The management server 28 decrypts the envelope 64A using the point-to-point encryption key 29 and processes the decrypted data necessary for forwarding the response transaction 66A to the mobile device 21. The payload 62 in the response transaction 66A is not decrypted since the management server 28 does not have access to end-to-end key 46.
The management server 28 re-encrypts some or all of the information in envelope 64A into envelope 64B. The envelope 64B is re-encrypted using the point-to-point key 27. A response message 66B is generated that includes the envelope 64B and end-to-end encrypted payload 62.
The response message 66B is transported to mobile device 21 over connection 23. The mobile device 21 decrypts the envelope 64B using encryption key 27 and decrypts the payload 62 using the encryption key 46. The decrypted payload 62 is then displayed on the mobile device 21. For example, emails from the mailbox 44 are displayed on the mobile device 21.
Encryption key 76 is negotiated between server 70 and server 74, encryption key 78 is negotiated between server 70 and server 72, and encryption key 80 is negotiated between server 72 and server 74. The negotiated encryption keys 76, 78 and 80 are used when processing the transactions 71 and 73.
For example, the transaction 73 may be sent from personal client 40 to server 74. The personal client 40 encrypts some or all of the envelope 75 in transaction 73 using the encryption key 29 and encrypts a payload 77 using encryption key 46. After receiving transaction 73, server 74 decrypts envelope 75 using encryption key 29.
Server 74 may then need to send the transaction 73 to server 70. Server 74 re-encrypts the decrypted envelope 75 using encryption key 76. Upon receiving message 73, server 70 decrypts envelope 75 using encryption key 76. After processing the contents, the server 70 re-encrypts the envelope 75 using the encryption key 27 previously negotiated with mobile device 21. The transaction 73 is then sent from server 70 to mobile device 21. Similar to
A synchronization transaction 71 on the other hand may need to be processed by all three servers 70, 72 and 74. A portion of the synchronization transaction 71 is encrypted using encryption key 27 when transported from mobile device 21 to server 70. Encryption key 78 is used for encrypting a portion of transaction 71 when transported from server 70 to server 72. Encryption key 80 is used to encrypt a portion of synchronization transaction 71 when transported from server 72 to server 74. Encryption key 29 is then used when the transaction 71 is transported from server 74 to PC 38.
Algorithms exist that allow secure negotiation of encryption keys between two nodes that are communicating directly with each other or that are communicating through intermediary nodes. One example of an encryption algorithm that allows secure key negotiation regardless of network topology is Elliptic Curve Cryptography Diffie-Hellman (ECC-DH).
A second portion 86 of transaction message 82 may include control information that only needs to be processed by one particular server. In this case, control data 86 is encrypted using a first point-to-point encryption key. A third portion of data 84 in transaction 82 may have other control information, for example, error checking data, that needs to be processed by a different server. Accordingly, the error checking data 84 is encrypted using a second point-to-point encryption key different than either of the other two encryption keys used for encrypting data 88 and 86.
It should be understood that this is only an example, and the devices shown in
The mobile device 21, management server 28, and the personal client 40 are all configured with an encryption schema 94 that identifies how specific items in the transaction 90 are to be encrypted. Each device is also configured with different security associations as described above in
Referring to
Request:
{auth_token = “abc”,
device_id = “xyz”,
method_id = “GetDocument”,
args = {path = “/docs”}
}
Mobile device 21 attaches an auth_token to transactions sent to the management server 28. For example, the mobile device 21 may be required to authenticate to the management server 28 by transmitting a username and password prior to being permitted to submit other transactions for processing. The server 28 issues the mobile device 21 an auth_token after successfully validating the username and password against information in the user database 42. The mobile device 21 then attaches the auth_token to subsequent transactions sent to the management server 28. The management server 28 uses the auth_token to identify and authenticate the source of each transaction and to determine where to route the transaction.
The device_id identifies the particular mobile device 21 sending the request 90. The device_id may be necessary for example when a user has more than one mobile device. The personal client 40 can use different device_id values to track when synchronization information was last sent to each of multiple different mobile devices. The device_id can also be used by either the management server 28 or the personal client 40 to determine how to format data sent to particular types of mobile devices 21. For example, data may need to be formatted differently for a cell phone as opposed to a personal computer. The device_id can also be used to correlate a known security association with a particular mobile device.
The method_id item in the example identifies a particular function GetDocument associated with request 90. The method_id item also requires the inclusion of related argument items that identify the parameters for the GetDocument function. For example, the argument items might include the expression path=“/docs” identifying the pathname where the requested documents are located.
Block 102 in
Encryption schema:
{GetDocument =
{clear = [“device id”],
pp = [“auth_token”, “user_id”],
ee = [“args.path”]
}
default = { pp }
}
Any items that do not require encryption are assigned to the data channel labeled “clear”. For example, the device_id item in the example is assigned to the channel “clear”. Items requiring the use of point-to-point encryption are assigned to data channel “pp” and therefore are encrypted using the PP key 27 as shown in
In this example, any item that is not explicitly declared in the encryption schema 94 is assigned by default to the “pp” channel. Since the method id item has not been specifically declared in the encryption schema 94, it is assigned to the “pp” channel by default and encrypted using the PP key 27.
It is important to note that the context of the communication determines the specific security association selected for encryption of a channel. For example, the first “pp” channel between mobile device 21 and management server 28 uses a security association different from the one established for the second, independently established “pp” channel between management server 28 and personal client 40. In this example, the first “pp” channel would employ the PP key 27 in
In order to prepare the request 90 for transmission, the mobile device 21 in block 104 of
Channels:
{clear = { device_id = “xyz”}
pp = {auth_token = “abc”, method id = “GetDocument”}
ee = {args = {path = {path = “/docs”} } }
}
In block 106, the channel contents are encoded (via a process commonly known as serialization) into arrays of bits or bytes referred to as data groups. These groupings of bits or bytes are referred to generally below as arrays but can be any type of partition, group, etc.
The contents of the clear channel are encoded into an array of bits referred to as data_group_1, the contents of the pp channel are encoded into an array of bits referred to as data_group_2, and the contents of the ee channel are encoded into an array of bits referred to as data_group_3. The contents of each channel need to be encoded into bit arrays so that they can be encrypted. The contents of the channels after being encoded into bit arrays are represented as follows.
Encoded
Channels:
{clear = data_group_1
pp = data_group_2
ee = data_group_3}
The bit arrays are then encrypted in block 108 according, to, the security association parameters for each channel. According to the encryption schema 94, bits in the clear channel (data_group_1) are not encrypted. The bits in the pp channel data_group_2 are encrypted using the point-to-point security association between mobile device 21 and management server 28, using PP key 27, and are referred to after encryption as pp_data_group_2. The bits in the ee channel data_group_3 are encrypted using the end-toend security association between mobile device 21 and personal client 40, using EE key 46, and are referred to after encryption as ee_data_group_3. The data groups are represented as follows after encryption:
Encoded
Channels:
{clear = data_group_1
pp = pp_data_group_2
ee = ee_data_group_3}
The bits making up the encrypted and unencrypted channels are then encoded into one or more packets in block 110. For clarity, the description below will refer to a single packet, however, the data from the channels may be contained in multiple packets. Some of the contents of the packet are shown below.
Packet
Header
length
version
flags
Payload
count = 3
“clear”
data_group_1
“pp”
pp_data_group_2
“ee”
ee_data_group_3
Information in the packet header may include the packet length, a version number, and other flags. The packet payload includes a count identifying 3 pairs of items. The three items include the non-encrypted contents in the clear channel, the pp encrypted contents of the pp channel, and the ee encrypted contents of the ee channel. The packet is then transported by mobile device 21 in block 112 to the management server 28.
Referring to
The data in the clear channel does not need to be decrypted. The transfer agent in block 118 decrypts the only bits in channels for which it has a known security association. The transfer agent, as a member of the point-to-point security association between mobile device 21 and management server 28, possesses the PP key 27 and therefore decrypts the contents of the pp channel. The transfer agent is not a member of the end-to-end security association between mobile device 21 and personal client 40, does not have the EE key 46 and therefore does not decrypt the data in the ee channel. Decryption produces the following data groups: clear ′=data_group_1, pp=data_group_2, and ee=ee_data_group_3.
The transfer agent in block 120 decodes the contents of the clear and pp channels. The contents of the encrypted ee channel are not decoded, but instead are maintained in an unmodified state for eventual transport to the personal client 40. Decoding produces the following contents.
Decoded
Channels:
{clear = {device id = “xyz”}
pp = {auth token = “abc”, method id = “GetDocument”}
ee=ee_data_group_3
}
In block 122 a partial request is formed by merging the items of the clear and pp channels. The partial request in this example could look similar to the following:
Partial Request:
{auth_token = “abc”,
device_id = “xyz”,
method_id = “GetDocument”,
args = { }
encrypted = {ee=ee_data_group_3}
}
The transfer agent in block 124 processes the partial request. In this example, the transfer agent may verify the request is authorized by matching the value of auth token (“abc”) with contents in the user database 42 (
The transfer agent may identify a user id=“joe” associated with the auth_token=“abc” and generate the following new request.
New Request:
{user_id = “joe”,
device_id = “xyz”,
method_id = “GetDocument”,
args = { }
encrypted = {ee=ee_data_group_3}
}
In block 126 the transfer agent performs another pattern match of the new request with the encryption schema 94 to reform the channel contents associated with the different security associations. In this example, the items in the clear, pp, and ee channels are fairly similar to the items originally sent by the mobile device 21. The reformed channel contents are shown below.
Channels Reformed
by Transfer Agent:
{clear = device_id = “xyz”}
pp = {user_id = “joe”, method_id =
“GetDocument”}
ee = ee_data_group_3
}
The transfer agent in block 128 encodes the contents of the clear channel into a bit array (clear=data_group_1). Since the encryption schema 28 defines no encryption for the clear channel, the bit array data_group_1 is not encrypted. The contents of the pp channel are encoded into a bit array pp=data_group_2 and then encrypted using the point-to-point security association between the management server 28 and the personal client 40, using PP key 29, forming the encrypted bit array pp=pp_data_group. The contents of the ee channel have never been decrypted or decoded by the transfer agent and therefore do not need to be re-encoded or encrypted. The following represents the bit arrays for reformed transaction.
Encoded/encrypted
Channels:
{clear = data_group_1
pp = pp_data_group_2
ee = ee_data_group_3}
The transfer agent in block 130 encodes the channel contents into a packet format similar to that shown above. The packet is then transported to the personal agent 40 in block 132.
Referring to
Encoded/encrypted
Channels:
{clear = data_group_1
pp = pp_data_group_2
ee = ee_data_group_3}
The personal client 40 has the PP key 29, the EE key 46, and knowledge of the relevant security associations. Therefore the contents of both the pp channel and the ee channel are decrypted in block 144 generating the following decrypted bit arrays.
Decrypted
Channels:
{clear = data_group_1
pp = data_group_2
ee = data_group_3}
The contents of the channels are then decoded in block 146 generating the following request items.
Decoded
Channels:
{clear = { device_id = “xyz”}
pp = {user_id = “joe”,
method_id = “GetDocument”}
ee = {args = {path = “/docs”}
}
The contents of the channels are then merged together in block 148 forming the reformed request 90 with the auth_token replaced with the user_id.
Request 90:
{device_id = “xyz”,
user_id = “joe”,
method_id = “GetDocument”
args = {path = “/docs”}
}
The personal client 40 processes the request 90 in block 150. Pursuant to the request 90, the personal client 40 retrieves the identified documents and then creates a reply transaction 91 (
Request 91:
{method_id = “GetDocumentResponse”,
args = {document = xxx,
size = 5123,
content_type = “text/plain”,
name = “readme.txt”}
}
According to the encryption schema, the method id may be encrypted using the PP key 29 and the remainder of the contents in reply 91 may be encrypted using the EE key 46.
Data Streaming
Referring to
In one example, predetermined maximum packet length is configured to be 1000 bytes. If the transaction 160 is determined to be less than 1000 bytes, the contents of the clear, pp, and ee channels are encoded into a single packet. However, in this example, it is determined that 500 bytes of data exist in the pp channel and 4500 bytes of data exist in the ee channel. All the contents of the pp channel are encoded into a 500 byte packet 164. The data from the ee channel is encoded into four separate 1000 byte packets 166-174 and one 500 byte packet 174.
A header packet 162 is formed that identifies all the packets 162-174 as part of the same transaction 160. The data in the header packet 162 is unencrypted. Since the header packet 162 is unencrypted, it can also contain data from the clear channel. Alternatively, data from the clear channel can be encoded into a separate unencrypted packet. The header packet 162 identifies 500 bytes of data encrypted using the PP encryption key and 4,500 bytes of data encrypted using the EE encryption key.
The node receiving the message 160 reads the header 162 and determines the transaction 160 is a multipacket message (streaming=true). In one embodiment, the clear packet header 162 always comes first and is immediately followed by the pp packet 164. The pp packet 164 is immediately followed by .ee packets 166-174. This order can be guaranteed using protocols such as Transmission Control Protocol/Internet Protocol (TCP/IP). Transmitting the packets in this predetermined order eliminates having to attach labels to each packet to identify the type of encryption. Alternatively, sequence numbers can be assigned to the packets 162-174.
The node receiving transaction 160 may receive, decrypt and decode different portions of the transaction 160 at a time. For example, the processing node may first process the unencrypted clear data in the header packet 162 to determine if the transaction 160 is unauthorized. If the transaction is not authorized, the processing node can discard the remainder of the transaction 160 without having to decrypt and decode the pp packet 164 and ee packets 166-174.
If the information in the header packet 162 is authorized, the processing node decrypts and decodes data in the pp packet 164. If the data in the pp packet 164 is invalid or has been tampered with, the remaining ee packets 166-174 can be discarded without being further processed.
The system described above can use dedicated processor systems, micro controllers, programmable logic devices, or microprocessors that perform some or all of the operations. Some of the operations described above may be implemented in software and other operations may be implemented in hardware.
For the sake of convenience, the operations are described as various interconnected functional blocks or distinct software modules. This is not necessary, however, and there may be cases where these functional blocks or modules are equivalently aggregated into a single logic device, program or operation with unclear boundaries. In any event, the functional blocks and software modules or features of the flexible interface can be implemented by themselves, or in combination with other operations in either hardware or software.
Having described and illustrated the principles of the invention in a preferred embodiment thereof, it should be apparent that the invention may be modified in arrangement and detail without departing from such principles. We claim all modifications and variation coming within the spirit and scope of the following claims.
Fiatal, Trevor A., Boynton, Lee R., Burke, Scott M., Sikes, Mark
Patent | Priority | Assignee | Title |
11522838, | Jan 08 2002 | Seven Networks, LLC | Secure end-to-end transport through in intermediary nodes |
Patent | Priority | Assignee | Title |
6877095, | Mar 09 2000 | Microsoft Technology Licensing, LLC | Session-state manager |
6957346, | Jun 15 1999 | SSH Communications Security OYJ | Method and arrangement for providing security through network address translations using tunneling and compensations |
7814208, | Apr 11 2000 | Leidos, Inc | System and method for projecting content beyond firewalls |
20010047474, | |||
20020178370, |
Executed on | Assignor | Assignee | Conveyance | Frame | Reel | Doc |
Mar 06 2003 | BOYNTON, LEE R | Seven Networks, Inc | ASSIGNMENT OF ASSIGNORS INTEREST SEE DOCUMENT FOR DETAILS | 052651 | /0947 | |
Mar 06 2003 | FIATAL, TREVOR A | Seven Networks, Inc | ASSIGNMENT OF ASSIGNORS INTEREST SEE DOCUMENT FOR DETAILS | 052651 | /0947 | |
Mar 06 2003 | BURKE, SCOTT M | Seven Networks, Inc | ASSIGNMENT OF ASSIGNORS INTEREST SEE DOCUMENT FOR DETAILS | 052651 | /0947 | |
Mar 06 2003 | SIKES, MARK | Seven Networks, Inc | ASSIGNMENT OF ASSIGNORS INTEREST SEE DOCUMENT FOR DETAILS | 052651 | /0947 | |
Jul 14 2015 | Seven Networks, Inc | Seven Networks, LLC | ENTITY CONVERSION | 052655 | /0369 | |
May 13 2020 | Seven Networks, LLC | (assignment on the face of the patent) | / |
Date | Maintenance Fee Events |
May 13 2020 | BIG: Entity status set to Undiscounted (note the period is included in the code). |
Jun 03 2024 | REM: Maintenance Fee Reminder Mailed. |
Nov 18 2024 | EXP: Patent Expired for Failure to Pay Maintenance Fees. |
Date | Maintenance Schedule |
Oct 13 2023 | 4 years fee payment window open |
Apr 13 2024 | 6 months grace period start (w surcharge) |
Oct 13 2024 | patent expiry (for year 4) |
Oct 13 2026 | 2 years to revive unintentionally abandoned end. (for year 4) |
Oct 13 2027 | 8 years fee payment window open |
Apr 13 2028 | 6 months grace period start (w surcharge) |
Oct 13 2028 | patent expiry (for year 8) |
Oct 13 2030 | 2 years to revive unintentionally abandoned end. (for year 8) |
Oct 13 2031 | 12 years fee payment window open |
Apr 13 2032 | 6 months grace period start (w surcharge) |
Oct 13 2032 | patent expiry (for year 12) |
Oct 13 2034 | 2 years to revive unintentionally abandoned end. (for year 12) |